Abstract
Metals deform plastically at the asperity level when brought in contact with a counter body even when the nominal contact pressure is small. Modeling the plasticity of solids with rough surfaces is challenging due to the multi-scale nature of surface roughness and the length-scale dependence of plasticity. While discrete-dislocation plasticity (DDP) simulations capture size-dependent plasticity by keeping track of the motion of individual dislocations, only simple two-dimensional surface geometries have so far been studied with DDP. The main computational bottleneck in contact problems modeled by DDP is the calculation of the dislocation image fields. We address this issue by combining two-dimensional DDP with Green’s function molecular dynamics. The resulting method allows for an efficient boundary-value-method based treatment of elasticity in the presence of dislocations. We demonstrate that our method captures plasticity quantitatively from single to many dislocations and that it scales more favorably with system size than conventional methods. We also derive the relevant Green’s functions for elastic slabs of finite width allowing arbitrary boundary conditions on top and bottom surface to be simulated.
Highlights
Modeling the contact mechanics of solid bodies assuming realistic surface roughness is highly relevant to tribology, the science of friction
In order to being able to study indentation using realistic surface geometries, we here combine the accurate description of plasticity offered by discrete-dislocation plasticity (DDP) with the fastly converging elastic solution delivered by GFMD, in a modeling technique which we name Green’s function dislocation dynamics (GFDD)
We propose a modeling technique, GFDD, which combines GFMD with DDP
Summary
Modeling the contact mechanics of solid bodies assuming realistic surface roughness is highly relevant to tribology, the science of friction. In order to being able to study indentation using realistic surface geometries, we here combine the accurate description of plasticity offered by DDP with the fastly converging elastic solution delivered by GFMD, in a modeling technique which we name Green’s function dislocation dynamics (GFDD). This is not the first attempt to combine dislocation dynamics with a boundary element method [43,44,45,46].
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